A novel precision-cut lung slice stretch model using removable inflation materials

Stretch is an important biomechanical stimulus facilitating tissue development in the respiratory system by programming the epithelium, endothelium, and extracellular matrix (ECM). Lung tissue undergoes stretch induced lung differentiation under normal prenatal and postnatal development. Furthermore, supraphysiological and aberrant stretch responses are known mechanisms of acute lung injury and ECM disruption. Current in vitro human tissue cyclic mechanical stretch (CMS) models suffer from significant, well-recognized disadvantages and are poorly validated in vivo for longer-term study. In vitro precision-cut lung slice (PCLS) models are commonly used to study the complex structural arrangement and cellular interactions of human tissue, as well as various lung diseases, including BPD.3 PCLS maintain lung tissue architecture and the variety of cell types present in the lung, allowing for a more realistic imitation of the lung microenvironment.3 Existing agarose-inflated PCLS models are hindered by retention of agarose media in the tissue, affecting material properties and complicating stretch studies. Our novel PCLS approach utilizes several technical innovations including a removable hydrogel for inflation and uses supportive poly(ethylene glycol) (PEG) hydrogels enable improved viability and phenotype retention during cyclic mechanical stretch (CMS). This platform will induce PCLS CMS for biochemical assays (e.g. transcriptomics, proteomics) after exposure.